The earth's internal structure and discontinuities, seismic waves, continental drift and sea-floor spreading, the major plates and the three boundary types, volcanoes and earthquakes, and the landforms built and worn by endogenic and exogenic forces
Geomorphology is the structural floor of the entire physical-geography syllabus, and it is one of the most reliably tested geography areas in CAPF Paper I because it is dense with named, objective facts: the discontinuities, the three seismic waves and what they prove, the layers and their depths, the seven major plates with one example each of divergent, convergent and transform motion, the volcano and earthquake belts, and a long vocabulary of erosional and depositional landforms. Almost every fact here is a clean single-correct, matching, or statement-based question. This note follows NCERT Class XI Fundamentals of Physical Geography (chapters on the interior of the earth, geomorphic processes and landforms) and G.C. Leong's Certificate Physical and Human Geography, which remain the standard CAPF anchors. India's own seismic exposure (the Himalaya, the Andaman arc, the Bhuj fault) ties this directly to the disaster-response role of the central forces.
We cannot dig to the centre, so the interior is read indirectly through earthquake (seismic) waves recorded on seismographs, plus volcanic material and meteorite evidence. Earthquakes generate body waves (travelling through the interior) and surface waves (travelling along the surface).
The P-wave shadow zone (between about 105 and 145° from the epicentre) and the S-wave shadow zone (beyond about 105°) together fix the size and state of the core.
From outside in, the earth is layered by composition and state, separated by sharp boundaries (discontinuities) where wave velocity changes:
Alfred Wegener (1912) proposed continental drift: a single supercontinent, Pangaea, surrounded by the ocean Panthalassa, split into Laurasia (north) and Gondwana (south), which then drifted apart. His evidence was the jigsaw fit of coastlines, matching fossils (Mesosaurus, Glossopteris), matching rock and mountain belts across oceans, and ancient glacial deposits in now-tropical lands. He could not explain the driving force, which weakened the theory.
Harry Hess (1960s) proposed sea-floor spreading: new ocean crust forms at mid-ocean ridges, spreads outward, and is destroyed at trenches. Proof came from palaeomagnetism (symmetrical magnetic stripes either side of ridges recording reversals of the earth's field) and from the youngest ocean rocks lying at the ridge and the oldest near the continents.
Plate tectonics (1960s) unified all of this: the lithosphere is broken into rigid plates that move over the asthenosphere, driven by mantle convection currents, aided by ridge push and slab pull. There are seven major plates and several minor ones (Nazca, Cocos, Caribbean, Philippine, Arabian, Scotia, Juan de Fuca).
A volcano is a vent through which magma, gases and pyroclastic material escape. Classified by activity into active (Etna, Stromboli, Kilauea), dormant (Vesuvius, Fujiyama), and extinct (Aconcagua, Deccan vents). Classified by form into shield (broad, gentle, basaltic, like Mauna Loa, Hawaii), composite or strato (steep, alternating lava and ash, like Fujiyama and Vesuvius), cinder cone (small, steep, ash), and caldera (a vast collapsed crater). Intrusive (plutonic) igneous forms include the batholith, laccolith, sill, dyke and phacolith. The Pacific Ring of Fire, a horseshoe of subduction zones, holds about two-thirds of the world's active volcanoes and most great earthquakes. Hot-spot volcanism (a fixed mantle plume) builds chains like the Hawaiian Islands away from any plate boundary.
The focus (hypocentre) is the point of energy release inside the earth; the epicentre is the point on the surface directly above it. Earthquakes are caused mostly by tectonic stress released along faults, and also by volcanic activity, reservoir loading (induced seismicity behind large dams) and collapse. Magnitude (energy released) is measured on the Richter scale (logarithmic, so each whole step is about 32 times more energy; the moment magnitude scale is now preferred for large quakes). Intensity (felt effects and damage) is measured on the modified Mercalli scale, running from I (not felt) to XII (total destruction). A submarine earthquake or landslide can displace water and generate a tsunami. Most earthquakes lie in two great belts: the Circum-Pacific belt (the Ring of Fire) and the Alpine-Himalayan (Mediterranean-Himalayan) belt, both at convergent plate margins.
Geomorphology rests on three rock families, a frequent matching question:
The slow conversion among these three under the agents of melting, weathering, deposition and metamorphism is the rock cycle.
Endogenic forces act from within (tectonic movement, volcanism, earthquakes) and build relief: they are the constructive force. They include diastrophism (slow building, splitting into epeirogenic vertical movements and orogenic mountain-building movements) and sudden movements (earthquakes, volcanism). Exogenic forces act from without (weathering, mass wasting, and the erosional and depositional work of rivers, glaciers, wind, waves and groundwater) and wear relief down: they are the destructive force, ultimately powered by the sun and gravity. The net result is gradation, the levelling of the land by degradation (wearing down) and aggradation (filling up).
Weathering is the in-situ breakdown of rock, with no transport; erosion is breakdown plus removal by an agent. Weathering has three modes:
Mass wasting (mass movement) is the downslope movement of rock and soil under gravity: slow creep, slumps, mudflows, and rapid landslides and rockfalls. It is a major hazard in the young, steep, rain-soaked Himalaya.
Each erosional agent works through a sequence of forms. The Davisian "cycle of erosion" carries a fluvial landscape through stages of youth (active downcutting, V-shaped valleys, waterfalls), maturity (graded slopes, meanders) and old age (broad flood plains, ox-bow lakes, deltas), ending in a near-level peneplain interrupted only by resistant monadnocks. Glaciers carve in the highlands and deposit in the lowlands; wind sculpts and drifts in deserts; groundwater dissolves limestone into karst; and waves cut and build along coasts. The landform tables below summarise the products.
| Feature | Fact |
|---|---|
| Crust-mantle boundary | Mohorovicic (Moho) discontinuity |
| Within-crust boundary (sial-sima) | Conrad discontinuity |
| Upper-lower mantle boundary | Repetti discontinuity |
| Mantle-core boundary | Gutenberg discontinuity, about 2,900 km |
| Outer-inner core boundary | Lehmann discontinuity |
| Rigid plate layer | Lithosphere (crust + uppermost mantle) |
| Plastic layer below | Asthenosphere (upper mantle) |
| Outer core state | Liquid (creates the S-wave shadow zone) |
| Inner core state | Solid (centre at about 6,371 km) |
| Core composition | Iron and nickel (nife); source of magnetic field |
| Continental crust | Sial, granitic, average about 30 km thick |
| Oceanic crust | Sima, basaltic, about 5 km thick |
| Fastest wave / passes through liquid | P-wave (longitudinal) |
| Cannot pass through liquid | S-wave (transverse) |
| Most destructive wave | L-wave (surface) |
| Supercontinent / surrounding ocean | Pangaea / Panthalassa |
| Northern and southern split of Pangaea | Laurasia and Gondwana |
| Sea-floor spreading proposed by | Harry Hess |
| Continental drift proposed by | Alfred Wegener |
| Magnitude scale | Richter (logarithmic) / moment magnitude |
| Intensity scale | Modified Mercalli |
| Hot-spot volcanism example | Hawaiian Islands |
| Largest active-volcano belt | Pacific Ring of Fire |
| Deccan Traps | Basaltic flood basalts (past volcanism) |
| Major plate | Boundary example |
|---|---|
| Pacific | Subducts along the Ring of Fire; San Andreas transform |
| North American | Mid-Atlantic Ridge (divergent, west side) |
| South American | Andes (Nazca subducts beneath it) |
| Eurasian | Himalaya (Indian plate collides) |
| African | East African Rift (splitting); Mid-Atlantic Ridge |
| Indo-Australian | Pushes into Eurasian plate, raising the Himalaya |
| Antarctic | Surrounded by spreading ridges |
| Agent | Erosional landforms | Depositional landforms |
|---|---|---|
| River | V-shaped valley, gorge, canyon, waterfall, rapids, meander, pot-hole | Alluvial fan, flood plain, natural levee, delta, ox-bow lake |
| Glacier | Cirque (corrie), arete, horn, U-shaped valley, hanging valley, fjord, roche moutonnee | Moraine, drumlin, esker, kame, outwash plain, erratic |
| Wind (arid) | Yardang, mushroom (pedestal) rock, deflation hollow, inselberg, ventifact | Barchan and seif dunes, loess |
| Groundwater (karst) | Sinkhole (doline), swallow hole, cavern, lapies | Stalactite, stalagmite, pillar, travertine |
| Sea wave | Sea cliff, wave-cut platform, sea cave, arch, stack, stump | Beach, spit, bar, tombolo, lagoon |
| Form | Character | Example |
|---|---|---|
| Shield volcano | Broad, gentle slopes, fluid basaltic lava | Mauna Loa (Hawaii) |
| Composite / strato | Steep cone, alternating lava and ash, andesitic | Fujiyama, Vesuvius |
| Cinder cone | Small, steep, loose ash and cinder | Paricutin (Mexico) |
| Caldera | Vast collapsed crater | Krakatoa, Yellowstone |
| Flood basalt | Vast fissure lava sheets | Deccan Traps, Columbia Plateau |
| Batholith / laccolith | Large / dome-shaped intrusion | (intrusive, plutonic) |
| Sill / dyke | Horizontal / vertical sheet intrusion | (intrusive) |
| Range | Continent | Plate collision |
|---|---|---|
| Himalaya-Karakoram | Asia | Indian into Eurasian |
| Alps | Europe | African into Eurasian |
| Andes | South America | Nazca under South American |
| Rockies | North America | Pacific / Juan de Fuca margin |
| Atlas | North Africa | African and Eurasian |
| Zagros | West Asia | Arabian into Eurasian |
| Feature / event | Location | Note |
|---|---|---|
| Mount Etna, Stromboli, Vesuvius | Italy | Active and historically destructive (Pompeii, 79 AD) |
| Krakatoa | Indonesia | Catastrophic 1883 caldera eruption |
| Mount St Helens | USA | 1980 lateral blast |
| Kilauea, Mauna Loa | Hawaii | Shield, hot-spot volcanoes |
| Fujiyama | Japan | Composite cone, dormant |
| Ojos del Salado | Chile-Argentina | Highest volcano on earth |
| 2004 Indian Ocean tsunami | Sumatra subduction zone | Hit the Andaman and Nicobar Islands and Tamil Nadu |
| 2001 Bhuj earthquake | Kachchh, Gujarat | Intraplate quake in seismic zone V |
| 2015 Gorkha earthquake | Nepal | On the Himalayan thrust; relief role for the ITBP |
India rides the Indian (Indo-Australian) Plate, which is still driving north into the Eurasian Plate, so the Himalaya keep rising and the entire Himalayan arc is seismically alive (Bureau of Indian Standards zones IV and V cover the Himalaya, the north-east and the Kachchh region; zone V is the highest hazard). This is not academic for the central forces: the ITBP and the Army are first responders to high-altitude earthquakes, avalanches and glacial-lake outburst floods on the LAC, as seen after the 2015 Nepal (Gorkha) earthquake and the 2021 Chamoli disaster. The Andaman and Nicobar Islands sit on the Sunda subduction arc and were India's landfall for the 2004 Indian Ocean tsunami, a standing reason for the integrated tri-service Andaman and Nicobar Command. The 2001 Bhuj earthquake in the seismically active Kachchh sits on the same plate-boundary stress. See india physiography and india borders neighbours and strategic geography.
Formats: single-correct on discontinuities, wave properties, layer states and depths; matching plate-boundary type to example, erosional agent to landform, volcano type to form; statement-based assertions on subduction and wave behaviour; and map-based location of the Ring of Fire, the Mid-Atlantic Ridge and the San Andreas Fault.
Authored practice: